Flat panel display and drive chip thereof

ABSTRACT

A flat panel display mainly includes a display panel and a plurality of drive IC chips mounted on the display panel by a chip-on-glass method. The display panel includes a plurality of electrode terminals, a plurality of external terminals and a plurality of first conductive traces. One surface of each drive IC chip is provided with a plurality of output terminals, a plurality of input terminals and a plurality of second conductive traces. The flat panel display is characterized in that corresponding input terminals on adjacent drive IC chips are electrically connected to one another through the first conductive traces of the display panel and the second conductive traces of the drive IC chips.

CROSS REFERENCE

This claims priority from Taiwan Patent Application No. 090127361 filedon Oct. 31, 2001, incorporated herein by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a flat panel display (FPD) in which adrive integrated circuit (IC) chip is mounted onto a display panel by achip-on-glass (COG) method. The present invention also relates to adrive IC chip for a flat panel display.

2. Description of the Related Art

For small size and low power consumption, flat panel display devicessuch as LCD (Liquid Crystal Display), PDP (Plasma Display Panel), ELD(Electroluminescent Display), and VFD (Vacuum Fluorescent Display) havebeen introduced. In these flat panel display devices, the LCD has beenmost widely adopted nowadays because of good picture quality and lowpower consumption. Although portable televisions and notebook computershaving the LCD have been marketed, there are various problems yet to besolved.

In an LCD, packaging techniques for connecting a drive IC chip, whichprovides a drive signal to the LCD panel, include wire bonding (WB),tape automated bonding (TAB) and chip-on-glass (COG) methods. In thesepackaging techniques, the chip-on-glass (COG) method has been mostactively researched recently because it can increase the density of theliquid crystal display element and minimize external size of the LCD inspite of various disadvantages.

However, when a plurality of integrated circuit chips are mounted on onesurface of a glass substrate, a wide area is required to wire the buslines for transmitting the common signals such as power supply and datasignal between the chips. This greatly reduces the available area of thesurface of the glass substrate. Typically, the bus lines are formed fromthe conductive layers such as ITO (Indium Tin Oxide) layer on thesubstrate thereby significantly increasing the resistance of the buslines.

U.S. Pat. No. 5,402,255, issued on Apr. 3, 1995 to Nakanishi et al.,discloses a device utilizing the internal circuits of drive IC chips totransmit the common signals between the chips. Referring to FIG. 1,Nakanishi et al. disclose a drive chip 100 having output terminals 110for providing drive signals to an LCD panel. The left-hand andright-hand terminals 120 and 130 for input and output signals areconnected to each other through an internal circuit 140 of the chip 100.Typically, the internal circuit of IC chip is made of aluminum alloy.Although aluminum alloy has higher electrical conductivity as comparedwith ITO, the problems of signal distortion or voltage (or IR) drop arestill observed. Furthermore, when extra metal traces are built into thearchitecture of a chip, the manufacturing process of wafer becomescomplicated thereby increasing the production cost.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a compact and highlyreliable flat panel display with drive IC chips directly mounted on itsglass substrate.

It is another object of the present invention to provide a flat paneldisplay which overcomes the problems of signal distortion or voltage (orIR) drop due to the electrical resistance of wiring connected betweendrive IC chips mounted on the panel.

It is still another object of the present invention to provide a driveIC chip for a flat panel display wherein one surface of the drive ICchip is provided with output/input terminals and conductive traces forestablishing electric connection with another drive IC chip.

To achieve the above listed and other objects, the present inventionprovides a flat panel display mainly comprising a display panel and aplurality of drive IC chips mounted on the display panel by achip-on-glass method. The display panel includes a plurality ofelectrode terminals for receiving drive signals, a plurality of externalterminals and a plurality of first conductive traces. One surface ofeach drive IC chip is provided with a plurality of output terminals, aplurality of input terminals and a plurality of second conductivetraces. The output terminals are electrically connected to the electrodeterminals of the display panel for transmitting drive signals. The inputterminals are electrically connected to the external terminals of thedisplay panel for receiving a common signal to control the drive ICchips. The flat panel display is characterized in that correspondinginput terminals on adjacent drive IC chips are electrically connected toone another through the first conductive traces of the display panel andthe second conductive traces of the drive IC chips. Each of the drive ICchips has a plurality of metal bumps such as gold bumps formed on theoutput terminals thereof, and the second conductive traces on each driveIC chip are made of the same material, i.e., gold that forms the metalbumps.

It is noted that signals are transmitted between the drive IC chipsmounted on the panel mainly through the second conductive traces ofgold. This significantly reduces the problems of signal distortion orvoltage (or IR) drop due to the electrical resistance of wiring, sincegold has an excellent electrical conductivity as compared toconventional aluminum alloy or ITO. Therefore, a reliable flat paneldisplay is obtained. Furthermore, the use of the second conductivetraces on the chips enables the space required to wire the bus lines tobe reduced thereby further reducing the overall size of the obtainedflat panel display.

To achieve the above listed and other objects, the present inventionfurther provides a drive integrated circuit chip having opposing firstand second edges for a flat panel display. One surface of the driveintegrated circuit chip is provided with a plurality of outputterminals, a plurality of input terminals and a plurality of secondconductive traces. The input terminals are arranged along the firstedge, and the second conductive traces comprise at least one lead havinga first end portion formed on one of the input terminals and a secondend portion formed corresponding to the second edge of the drive ICchip. In this embodiment, only the output terminals have metal bumpsprovided thereon, and the protruding height of the second conductivetraces is substantially the same as the protruding height of the metalbumps. The first end portion and the second end portion of the lead areattached to the first conductive traces of the display panel by ananisotropic conductive adhesive film (ACF) such that the first endportion and the second end portion are electrically coupled to the firstconductive traces, respectively; meanwhile, the metal bumps on theoutput terminals are attached to the electrode terminals of the displaypanel by the same ACF such that the metal bumps are electrically coupledto the electrode terminals for transmitting drive signals.

According to another embodiment of the present invention, the drive ICchip further comprises at least one dummy pad arranged along the firstedge of the drive IC chip. The second conductive traces comprise atleast one lead having a first end connected to one of the inputterminals and a second end connected to the dummy pad. In thisembodiment, the input/output terminals and the dummy pad have metalbumps provided thereon, and the protruding height of the conductivetraces is substantially lower than the protruding height of the metalbumps. The metal bumps on the input terminals and the dummy pad areattached to the first conductive traces of the display panel by ananisotropic conductive adhesive film (ACF) such that the metal bumps areelectrically coupled to the first conductive traces; meanwhile, themetal bumps on the output terminals are attached to the electrodeterminals of the display panel by the same ACF such that the metal bumpsare electrically coupled to the electrode terminals for transmittingdrive signals.

According to the drive IC chip of the present invention, the secondconductive traces and the gold bumps are both formed by conventionalmethods on the backside surface of the drive IC chip, therebysimplifying the manufacturing process of wafer and reducing theproduction cost.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, advantages, and novel features of the invention willbecome more apparent from the following detailed description when takenin conjunction with the accompanying drawings.

FIG. 1 is a bottom plan view of a conventional drive IC chip;

FIG. 2 is a top plan view of a portion of a display panel according toan embodiment of the present invention;

FIG. 3 is a bottom plan view of a drive IC chip according to a firstembodiment of the present invention;

FIG. 4 is a bottom plan view of a drive IC chip according to a secondembodiment of the present invention; and

FIG. 5 is a top plan view of a portion of a flat panel display accordingto an embodiment of the present invention illustrating several drive ICchips mounted on the display panel of FIG. 2.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The flat panel display according to an embodiment of the presentinvention mainly comprises a display panel and a plurality of drive ICchips mounted on the display panel by a chip-on-glass (COG) method. Theflat panel display of the present invention is characterized in thatcorresponding input terminals on adjacent drive IC chips areelectrically connected to one another through the conductive tracesformed on the display panel as well as the drive IC chips.

FIG. 2 is a top plan view of a portion of a display panel 210 accordingto an embodiment of the present invention. The display panel 210 mainlycomprises a top plate 220 and a bottom plate 230 bonded to the top plate220. On the central region of the bottom plate 230, there are formed aplurality of parallel scan lines 232 and a plurality of parallel datalines 234 perpendicular to the scan lines 232. Although not shown, thesescan lines 232 and data lines 234 are insulated from each other throughan inter-layer insulating film. Moreover, the display region isconstructed within the region in which the scan lines 232 and the datalines 234 intersect, and the pixel region is a region which issurrounded by the two adjacent scan lines 232 and the two adjacent datalines 234. Specifically, in each pixel region, there are formed a thinfilm transistor (TFT) as the switching element, and a pixel electrode(not shown). It could be understood that the top plate 220 may be acolor filter (CF) substrate, and the bottom plate 230 may be a thin filmtransistor (TFT) substrate.

As shown in FIG. 2, the scan lines 232 and data lines 234 of the presentinvention have one ends forming the electrode terminals 236 adapted forconnecting to drive ICs. The bottom plate 230 further includes externalterminals 238 and first conductive traces 240. The external terminals238 are designed to be connected to an input device such as a data clockcontroller (not shown) for input common signals such as power supply,data signal, clock signal and address signal (chip select). Although thefirst conductive traces 240 are simply illustrated as parallel lines inFIG. 2, they may be arranged in other patterns. The first conductivetraces 240 are formed by patterning on the bottom plate 230 at locationscorresponding to the portion in which the drive IC chips will bemounted.

FIG. 3 shows a drive IC chip 250 according to a first embodiment of thepresent invention. The drive chip 250 has two opposing longer edges, twoopposing shorter edges and two opposing surfaces. One surface of thedrive chip 250 is provided with a plurality of output terminals 252, aplurality of input terminals 254 and a plurality of second conductivetraces. The output terminals 252 are arranged along the longer edge foroutput drive signals. The input terminals 254 are arranged along theshorter edge 250 a for input signals common to the drive integratedcircuits. The second conductive traces 256 comprise two leads 256 havingfirst end portions 256 a formed on the input terminals 254 and secondend portions 256 b formed corresponding to the other shorter edge 250 bof the drive chip 250. In this embodiment, only the output terminals 252have metal bumps 258 provided thereon. The metal bumps 258 may be formedby a conventional bumping technology comprising the steps of: (a)forming an under bump metallurgy (UBM) on the output terminals 252 ofthe drive chip 250 by, e.g., electroless nickel/gold plating, and (b)forming metal bumps on the UBM by, e.g., vapor deposition,electroplating or printing. Preferably, the metal bump 258 is a goldbump with at least about 90 weight percentage of Au. Typically, the goldbump is formed by the following steps: (a) Application of a photoresiston the drive chip 250 and its patterning to form opening at a locationcorresponding to the output terminal 252; and (b) Electrodeposition ofgold on the resist opening section to form the gold bump. It is notedthat the second conductive traces of the present invention can be formedusing the conventional process described above without introducing anyadditional step. That is accomplished by transferring a predeterminedpattern having the design of the second conductive traces integratedtherein during the step (a), and plating a layer of gold on the exposedarea of the second conductive traces to form the leads 256 during thestep (b). Preferably, the protruding height of the conductive traces,i.e., the leads 256, is substantially the same as the protruding heightof the metal bumps 258.

Referring to FIG. 5, the drive IC chips 250 are mounted on the bottomplate 230 of the display panel by a COG method. Specifically, althoughnot shown in FIG. 5, the chip 250 is attached to the bottom plate 230 ofthe display panel by an anisotropic conductive adhesive film (ACF). Onetype of anisotropic adhesive suitable for forming the ACF is known as a“z-axis anisotropic adhesive”. Z-axis anisotropic adhesives are filledwith conductive particles to a low level such that the particles do notcontact each other in the xy plane. Accordingly, compression of thematerial in the z direction establishes an electrical path. Therefore,the output terminals 252 are electrically connected to the electrodeterminals (not shown in FIG. 5) of the display panel for transmittingdrive signals through the metal bumps 258 and the conductive particlesof ACF. Referring to FIG. 3 and FIG. 5, the common signals are input tothe display panel through the external terminals 238 and are transmittedto the input terminals 254 of a drive chip 250 through the firstconductive trace 240, the first end portions 256 a of the leads 256 andthe conductive particles of ACF. Then, the common signals aretransmitted through the leads 256 (as shown by the dotted lines in FIG.5) to the second end portions 256 b thereof. Thereafter, the commonsignals are output to the input terminals 254 of another drive chip 250from the second end portions 256 b. In this way, corresponding inputterminals 254 on adjacent drive IC chips are electrically connected toone another through the first conductive traces 240 of the display paneland the second conductive traces on the surface of the drive IC chips.

FIG. 4 shows a drive IC chip 260 according to a second embodiment of thepresent invention. The drive chip 260 is characterized by the feature offurther comprising two dummy pads 262 arranged along the shorter edge250 b thereof. The second conductive traces comprise two leads 264having first ends connected to the input terminals 254 and second endsconnected to the dummy pads 262. It is noted that the dummy pads 262,the output terminals 252, the input terminals 254 and the secondconductive traces are formed on the same surface. The structure of thedummy pads 262 is substantially the same as the structure of theinput/output terminals 252, 254 with the exception that the dummy pads262 are not electrically connected to the inner circuit of chip. In thisembodiment, the input/output terminals 252, 254 and the dummy pads 262have metal bumps 258 provided thereon. Preferably, the protruding heightof the conductive traces, i.e., the leads 256, is substantially lowerthan the protruding height of the metal bumps 258 such that the area onthe bottom plate 230 for mounting the drive chips can be utilized forother wiring.

Referring to FIG. 5, the drive IC chips 260 may be attached to thebottom plate 230 of the display panel by an ACF, too. Therefore, theinput terminals 254 and the dummy pads 262 (see FIG. 4) are electricallyconnected to the first conductive traces 240 of the display panelthrough the metal bumps 258 and the conductive particles of ACF. In thisembodiment, the common signals input to the external terminals 238 aretransmitted to the input terminals 254 of a drive chip 260 through thefirst conductive trace 240, the metal bump 258 and the conductiveparticles of ACF. Then, the common signals are transmitted through theleads 264 (as shown by dotted lines in FIG. 5) to the dummy pads 262.Thereafter, the common signals are output to the input terminals 254 ofanother drive chip 260 from the dummy pads 262. In this way,corresponding input terminals 254 on adjacent drive IC chips areelectrically connected to one another through the first conductivetraces 240 of the display panel and the second conductive traces on thesurface of the drive IC chips.

According to the drive IC chip of the present invention, the secondconductive traces and the gold bumps are both formed by conventionalmethods on the backside surface of the drive IC chip, therebysimplifying the manufacturing process of wafer and reducing theproduction cost. In addition, since gold has an excellent electricalconductivity as compared to conventional aluminum alloy or ITO, theproblems of signal distortion or voltage (or IR) drop due to theelectrical resistance of wiring are significantly reduced, therebyobtaining a reliable flat panel display. Furthermore, the use of thesecond conductive traces on the chips enables the space required to wirethe bus lines to be significantly reduced thereby further reducing theoverall size of the obtained flat panel display.

Although the preferred embodiments in the present invention areexplained by means of liquid crystal displays of the COG type, it isspecifically contemplated that the present invention is widelyapplicable to various flat panel displays with drive chips mounted byCOG methods, including, but not limited to, PDP (Plasma Display Panel),ELD (Electroluminescent Display), OLED panel and VFD (Vacuum FluorescentDisplay).

Although the invention has been explained in relation to its preferredembodiment, it is to be understood that many other possiblemodifications and variations can be made without departing from thespirit and scope of the invention as hereinafter claimed.

1. A flat panel display comprising: a display panel including aplurality of electrode terminals for receiving drive signals, aplurality of external terminals and a plurality of first conductivetraces; and a plurality of drive IC chips mounted on the display panelby a chip-on-glass method, each of the drive IC chips having a pluralityof output terminals, a plurality of input terminals and a plurality ofsecond conductive traces provided on a surface thereof, the outputterminals being electrically connected to the electrode terminals of thedisplay panel, the input terminals being electrically connected to theexternal terminals of the display panel for receiving a common signal tocontrol the drive IC chips, wherein corresponding input terminals onadjacent drive IC chips are electrically connected to one anotherthrough the first conductive traces of the display panel and the secondconductive traces of the drive IC chips.
 2. The flat panel display asclaimed in claim 1, wherein the surface of each drive IC chip hasopposing first and second edges, the input terminals are arranged alongthe first edge of the drive IC chip, and the second conductive traces onthe drive IC chip comprise at least one lead having a first end portionformed on one of the input terminals and a second end portion formedcorresponding to the second edge of the drive IC chip.
 3. The flat paneldisplay as claimed in claim 2, wherein each of the drive IC chips has aplurality of metal bumps formed on the output terminals thereof, and thesecond conductive traces on each drive IC chip are made of the samematerial that forms the metal bumps.
 4. The flat panel display asclaimed in claim 3, wherein a protruding height of the second conductivetraces is substantially the same as the protruding height of the metalbumps, and the first end portion and the second end portion of the leadare attached to the first conductive traces of the display panel throughan anisotropic conductive adhesive film (ACF) such that the first endportion and the second end portion are electrically coupled to the firstconductive traces, respectively.
 5. The flat panel display as claimed inclaim 1, wherein the surface of each drive IC chip has opposing firstand second edges, each drive IC chip further comprises at least onedummy pad arranged along the first edge of the drive IC chip, the inputterminals are arranged along the second edge of the drive IC chip, andthe second conductive traces comprise at least one lead having a firstend connected to one of the input terminals and a second end connectedto the dummy pad.
 6. The flat panel display as claimed in claim 5,wherein each of the drive IC chips has a plurality of metal bumps formedon the output terminals, the input terminals and the dummy pads, and thesecond conductive traces on each drive IC chip are made of the samematerial that forms the metal bumps.
 7. The flat panel display asclaimed in claim 6, wherein a protruding height of the second conductivetraces is substantially lower than the protruding height of the metalbumps.
 8. The flat panel display as claimed in claim 1, wherein thedisplay panel is a liquid crystal display panel comprising a top plateand a bottom plate bonded to the top plate, the bottom plate is providedwith a plurality of parallel scan lines and a plurality of parallel datalines perpendicular to the scan lines, wherein the electrode terminalsfor receiving drive signals are formed as part of the scan lines or thedata lines.
 9. The flat panel display as claimed in claim 1, wherein thesecond conductive traces on each drive IC chip comprise at least onelead having a first end portion formed on one of the input terminals anda second, opposite end portion; each of the drive IC chips has aplurality of metal bumps formed on the output terminals thereof; and aprotruding height of the second conductive traces is substantially thesame as the protruding height of the metal bumps.
 10. The flat paneldisplay as claimed in claim 1, wherein each drive IC chip furthercomprises at least one dummy pad on said surface, and the secondconductive traces comprise at least one lead having a first endconnected to one of the input terminals and a second end connected tothe dummy pad; each of the drive IC chips has a plurality of metal bumpsformed on the output terminals, the input terminals and the dummy pads;and a protruding height of the second conductive traces is substantiallylower than the protruding height of the metal bumps.
 11. The flat paneldisplay as claimed in claim 1, wherein each of the second conductivetraces is an elongated conductive trace.
 12. The flat panel display asclaimed in claim 1, wherein each of the second conductive traces is anelongated conductive trace having opposite ends positioned adjacentopposite edges of the corresponding drive IC chip.
 13. The flat paneldisplay as claimed in claim 1, wherein the corresponding input terminalsof each pair of adjacent said drive IC chips are serially electricallyconnected by one of said first conductive traces and one of said secondconductive traces.
 14. The flat panel display as claimed in claim 13,wherein the corresponding input terminals of more than two said drive ICchips are serially electrically connected by said first and secondconductive traces to one of said external terminals of said displaypanel for receiving said common signal.
 15. The flat panel display asclaimed in claim 13, wherein each of the second conductive traces is anelongated conductive trace and has opposite first and second endportions, said first end portion defining one of the input terminals ofthe corresponding drive IC chip and said second end portion beingelectrically connected to the corresponding input terminal of anadjacent drive IC chip via one of said first conductive traces; and saidone of said first conductive traces also has opposite end portionsphysically bonded and electrically connected to said second end portionof said second elongated conductive trace and the corresponding inputterminal of said adjacent drive IC chip, respectively.
 16. A driveintegrated circuit chip for a flat panel display, the drive integratedcircuit chip comprising a plurality of output terminals, a plurality ofinput terminals and a plurality of conductive traces provided on asurface thereof, the conductive traces comprising at least one leadhaving a first end portion formed on one of the input terminals; whereinthe surface has opposing first and second edges, the input terminals arearranged along the first edge, and the lead having a second end portionformed corresponding to the second edge.
 17. A drive integrated circuitchip for a flat panel display, the drive integrated circuit chipcomprising a plurality of output terminals, a plurality of inputterminals and a plurality of conductive traces provided on a surfacethereof, the conductive traces comprising at least one lead having afirst end portion formed on one of the input terminals; said driveintegrated circuit chip further comprising a plurality of metal bumpsformed on the output terminals, and the conductive traces are made ofthe same material that forms the metal bumps.
 18. The drive integratedcircuit chip as claimed in claim 17, wherein a protruding height of theconductive traces is substantially the same as the protruding height ofthe metal bumps.
 19. A drive integrated circuit chip for a flat paneldisplay, the drive integrated circuit chip comprising a plurality ofoutput terminals, a plurality of input terminals and a plurality ofconductive traces provided on a surface thereof, the conductive tracescomprising at least one lead having a first end portion formed on one ofthe input terminals; said drive integrated circuit chip furthercomprising a plurality of metal bumps formed on the output terminals,wherein a protruding height of the conductive traces is substantiallythe same as the protruding height of the metal bumps.